On the Evolution of Reproductive Systems in Neurospora

Strandberg, Rebecka

January 2012

The aim of this thesis was to study the evolution of reproductive systems and reproductive traits in the fungal genus Neurospora. More specifically, I have investigated the evolutionary forces shaping the genes involved in sexual reproduction, focusing on mating-type (mat) and pheromone receptor (pre) genes. Neurospora contains species exhibiting three different mating systems, i.e., heterothallism (self-incompatibility), homothallism (self-compatibility) and pseudohomothallism (partial self-incompatibility). First, a robust phylogeny of Neurospora was established. The phylogenetic analyses revealed multiple independent transitions in reproductive life style during the evolutionary history of the genus. We argued for a heterothallic ancestor of the genus, although our subsequent ancestral reconstruction analyses favored a homothallic ancestor. To be able to settle the ancestral mating system, we zoomed in on the structural architecture of the mat-locus in four homothallic species of Neurospora, thought to have arisen from independent transitions. Our results led us to suggest two different genetic mechanisms (translocation and unequal crossover) to explain the transitions in mating system from heterothallism to homothallism. We pointed out that the mating-system transitions in Neurospora are unidirectional, and suggested that transposable elements might be driving the transitions. In conclusion, we suggest a heterothallic ancestor for Neurospora, and that at least six transitions to homothallism and two transitions to pseudohomothallism have occurred in its evolutionary history. Further, we used the phylogeny of Neurospora as a framework to test if the evolution of pre-genes (pre-1 and pre-2) in hetero- and homothallic Neurospora is dependent on mating systems and/or even the homothallic clades themselves (i.e., mating-system and/or switch-dependent). The molecular evolution results suggest that pre-1 and pre-2 are overall functional in both homothallic and heterothallic Neurospora. The molecular evolution of pre-1 seems to be independent of mating-system or homothallic clade, and we detected signs for positive selection in the C-terminal tail. For pre-2 we found no support for mating-system dependent evolution, but indications for switch-dependent evolution. In this study we also included expression analyses of both pre- as well as mat-genes, with the prospect to assess functionality and regulation. During this thesis work, we also performed a phylogenetic study were we found that reproductive genes might be more permeable to introgression than other genes, which is in contrast to theoretical expectations. In the last study, we confirmed the co-existence of two alternative splice variants of the pheromone receptor gene pre-1 in Neurospora crassa, and performed expression profiles studies using quantitative RT-PCR. I hope this thesis work will further strengthen Neurospora as a model for research in evolutionary genetics.

Neurospora

mating type

pheromone receptor

phylogeny

gene expression

heterothallism

homothallism

pseudohomothallism

alternative splicing

Sex in Cryptococcus: Signaling, Mating-type Locus Evolution and Gene Silencing

Hsueh, Yen-Ping

26 February 2008

<p>Fungi have a genetically controlled sex determination system, which is governed by a small, sex-specific region in the genome called the mating-type locus (MAT). In the basidiomycetous yeast Cryptococcus neoformans, the pathogen that causes cryptococcal meningitis and cryptococcosis, sex has been associated with virulence. To further understand how sex is genetically regulated in C. neoformans, we focused our studies on the evolution of the MAT locus and molecular dissection of the pheromone signaling pathway that controls sexual development. Two MAT-linked meiotic recombination hotspots that likely drove the assembly and rearrangement of MAT were identified. Fine mapping through the integration of genetic markers established that two hotspots, one on each side of the MAT locus, are located in an ~10 kb and ~5 kb region. Plotting the G + C content along MAT and the flanking regions revealed a strong association between the location of these two hotspots and a high G + C content. By deletion and insertion of the G + C rich region, we demonstrated that the high G + C rich region is required but not sufficient to induce recombination. On the other hand, to provide direct experimental evidence to support the previously proposed model for the evolution of MAT, we sought to recapitulate the ancestral tetrapolar, and the intermediate tripolar mating systems of C. neoformans by manipulating the MAT structure to model a tetrapolar system. In the two modified "a" and "α" strains, the sex-determining genes SXI1α or SXI2a residing at the MAT locus were disrupted and the wild-type allele of these two genes was then reintroduced at another genomic location (URA5) that is unlinked to MAT. Our results show that C. neoformans can complete the sexual cycle with a tetrapolar mating configuration and the transitional tripolar state might be under strong negative selection pressure, which could have facilitated the transition from a tripolar state to the final bipolar mating system. </p><p>The MAT locus is the major determinant of the sexual identity of a cell, but several signaling pathways, including the pheromone signaling pathway, are required to regulate mating and sexual development. Many components of the pheromone signaling pathway have been identified; however, it is less clear what lies upstream of the MAPK cascade. To address this question, we studied the role of two Gα subunits (Gpa2, Gpa3) in mating and concluded that they share both redundant and divergent roles in mating. gpa2 gpa3 double mutants, but neither gpa2 nor gpa3 single mutants, are sterile in bilateral crosses. In their GTP-bound form, they signal in opposition: Gpa2 promotes mating whereas Gpa3 inhibits. Furthermore, we also studied the functions of a novel upstream component Cpr2, a pheromone receptor-like gene, in pheromone signaling and sexual development. All lines of evidence suggest that Cpr2 is a constitutive ligand-independent receptor that, when expressed, engages the same G-proteins and activates the same pheromone signaling pathway as the canonical ligand-activated pheromone receptors. Expression of Cpr2 is induced post cell fusion during mating, and likely introduces a positive feedback loop to allow a self-perpetuating signaling state to enable efficient mating. Cells lacking this receptor are fertile, but produce abnormal filamentous structures. Overexpression of CPR2 in a or α cells strongly enhances fruiting, an alternative same-sex mating process in C. neoformans. Therefore, Cpr2 establishes a new paradigm for a naturally occurring constitutively active GPCR that governs cell fate in fungi. </p><p>Finally, we described a sex-induced silencing (SIS) phenomenon in C. neoformans. Using genetic approaches, we showed that SIS is triggered by a tandem insertion of a transgene during the sexual cycle. Interestingly, only a proportion of progeny carrying the transgene are silenced. Gene deletion, RIP, or DNA methylation do not contribute to SIS but the RNAi machinery is required. In conclusion, these studies provide further understanding of sex in C. neoformans from different perspectives, which invites comparisons to other fungal and even more broadly, eukaryotic pathogens to address the role of sex in evolution.</p> / Dissertation

Biology, Genetics

Biology, Microbiology

Biology, Genetics

Cryptococcus

signaling

recombination

pheromone receptor

G proteins